Alistair Simpson Irvine

CpG-island fragments from the HNRPA2B1/CBX3 genomic locus reduce silencing and enhance transgene expression from the hCMV promoter/enhancer in mammalian cells

BackgroundThe hCMV promoter is very commonly used for high level expression of transgenes in mammalian cells, but its utility is hindered by transcriptional silencing. Large genomic fragments incorporating the CpG island region of the HNRPA2B1 locus are resistant to transcriptional silencing.ResultsIn this report we describe studies on the use of a novel series of vectors combining the HNRPA2B1 CpG island with the hCMV promoter for expression of transgenes in CHO-K1 cells. We show that the CpG island gives at least twenty-fold increases in the levels of EGFP and EPO observed in pools of transfectants, and that transgene expression levels remain high in such pools for more than 100 generations. These novel vectors also allow facile isolation of clonal CHO-K1 cell lines showing stable, high-level transgene expression.ConclusionVectors incorporating the hnRPA2B1 CpG island give major benefits in transgene expression from the hCMV promoter, including substantial improvements in the level and stability of expression. The utility of these vectors for the improved production of recombinant proteins in CHO cells has been demonstrated.

Efficient nonviral transfection of dendritic cells and their use for in vivo immunization.

Immunization with dendritic cells (DCs) transfected with genes encoding tumor-associated antigens (TAAs) is a highly promising approach to cancer immunotherapy. We have developed a system, using complexes of plasmid DNA expression constructs with the cationic peptide CL22, that transfects human monocyte-derived DCs much more efficiently than alternative nonviral agents. After CL22 transfection, DCs expressing antigens stimulated autologous T cells in vitro and elicited primary immune responses in syngeneic mice, in an antigen-specific manner. Injection of CL22-transfected DCs expressing a TAA, but not DCs pulsed with a TAA-derived peptide, protected mice from lethal challenge with tumor cells in an aggressive model of melanoma. The CL22 system is a fast and efficient alternative to viral vectors for engineering DCs for use in immunotherapy and research.

Nitroreductase-based therapy of prostate cancer, enhanced by raising expression of heat shock protein 70, acts through increased anti-tumour immunity

Gene-directed enzyme-prodrug therapy (GDEPT) using nitroreductase (NTR), with efficient adenoviral delivery, and CB1954 (CB), is an effective means of directly killing tumours. However, an immune-mediated bystander effect remains an important product of GDEPT since it is often critical to the elimination of untransduced tumour cells both locally and at distal metastatic sites through generation of tumour-specific immunity without the need for tumour antigen identification or the generation of a personalised vaccine. The mode of induced tumour cell death is thought to contribute to the immunisation process, together with the induction and release of stress proteins. Here, RM-9 murine prostate tumour cells were efficiently killed by adenovirally delivered NTR/CB treatment both in vitro and in vivo, and bystander effects were observed. Cells appeared to die by pathways that suggest necrosis more than that of classical apoptosis. NTR/CB-induced expression of a range of stress proteins was determined by proteomic analysis, revealing chiefly heat shock protein (HSP)25 and HSP70 upregulation, whilst immune responses in vivo were weak. In an attempt to enhance the anti-tumour effect, an adenoviral vector was constructed that co-expressed NTR and HSP70, the latter being a known immune stimulator and chaperone of antigen. This combination elicited significantly enhanced protection over NTR alone for both the treated tumour and a subsequent re-challenge. Protection was CD4+ and CD8+ T cell-dependent and was associated with tumour-specific CTL, IFNγ and IL-5 responses. The use of such a cytotoxic and immunomodulatory gene combination in cancer therapy warrants further pursuit.

Antitumor immune responses mediated by adenoviral GDEPT using nitroreductase/CB1954 is enhanced by high-level coexpression of heat shock protein 70.

Gene-directed enzyme prodrug therapy (GDEPT) is a promising approach to local management of cancer through targeted chemotherapy. Killing localized tumors by GDEPT in a manner that induces strong antitumor cellular immune responses might improve local management and allow benefit in disseminated cancer. Here we evaluated the combination of nitroreductase (NTR)/CB1954 GDEPT with high-level expression of heat shock protein 70 (HSP70, a stress protein that can shuttle cytosolic peptides into antigen-presenting cells) for induction of antitumor immunity using adenovirus gene delivery in an aggressive and nonimmunogenic BALB/c syngeneic 4T1 breast cancer model. The mechanism of cell death and spectrum of stress proteins induced are likely to be important determinants of the resulting immune responses. We showed that NTR/CB1954 treatment of 4T1 cells gave both apoptotic and nonapoptotic killing. In vivo killing of 4T1 cells expressing NTR gave weak antitumor immunity and very limited induction of stress proteins including HSP70. High-level coexpression of HSP70 during NTR/CB1954-mediated killing of 4T1 cells in vivo gave much greater protection from tumor challenge (67% long-term survivors compared to 17%) and induced 4T1-specific cytotoxic T-cell responses. The enhancement of antitumor responses resulting from HSP70 coexpression was similar to that conferred by coexpression of GM-CSF.

The immune system versus cancer: can the immune system win?

A vast range of immunotherapeutic strategies are being considered for the treatment of cancer, only some of which are discussed above. Immunotherapy is unlikely to become a stand-alone treatment for cancer; it is far more likely that it will be used as a method to treat minimal residual disease or recurrence following more conventional treatment, such as surgical removal of primary tumour masses. This is emphasized by the fact that the effectiveness of treatment in animal models is more striking in the preventative, rather than the therapeutic, setting. The ultimate measure for the success of these approaches is clinical efficacy, but practical considerations must also be taken into account. For example, assuming equivalent efficacy and toxicity, relatively simple procedures such as cytokine administration will be preferable to manipulated autologous cell therapies. The immune status of patients is also a critical consideration when designing clinical trials and assessing results; many cancer patients are immunosuppressed either as a result of the cancer or of previous treatments.Assessment of the relative efficacy of the different approaches is currently very difficult because relative potency in animal models is rarely tested and, even if it were, would probably not be predictive of the potency in patients. However, over the next few years, as the results of ongoing, or imminent, clinical trials become available, a clearer picture of the potential of immunotherapy for the treatment of cancer will hopefully emerge, and, specifically, there might be indications as to which approaches show the most potency, with least toxicity, in patients. Thus, we hope to gain insights into the most promising approaches to help the immune system win this battle.